Loom for weaving patterned pile fabrics



July 26, 1949. J. H. HARDING 2,477,249

GENERALLY KNOWN AS H. J. HARDING L00 FOR WEAVING PATTERNED FILE FABRICS Filed Oct. 29, 1946 14 Sheets-Sheet 1 July 26, 1949. J. H. HARDING 2,477,249

GENERALLY KNOWN AS H. J. HARDING Loom FOR wmvmc PATTBRNED FILE FABRICS Filed 001;. 29. 1946 14 Sheets-Sheet 2 zmnr J. H. HARDING GENERALLY KNOWN AS H. J. HARDING LOO! FOR WEAVING PATTERNED FILE FABRICS July 26, 1949.

14 Sheets-Sheet 3 Filed Oct. 29. 1946.

A Wu M .3 n GM 1 mN M N 5 Nu m mww y 6, 1949. J. H. HARDING 2,477,249

GENERALLY KNOWN AS H. J. HARDING LOOII FOR WEAVING PATTERNED PILE FABRICS Filed Oct. 29, 1946 14 Sheets-Sheet 4 N '9 *0 N N N J. H. HARDING GENERALLY KNOWN AS H. J. HARDING LOOM FOR WEAVING PATTERNED FILE FABRICS July 26, 1949.

14 Sheets-Sheet 5 Filed Oct. 29, 1946 y 9- H. HARDING Q 2,477,249

GENERALLY KNOWN AS H. J. HARDING LOO]! FOR WEAVING PATTERNED PILE FABRICS Filed Oct. 29, 1946 14 Sheets-Sheet 6 I? n N v July 26, 1949.- J. H. HARDING GENERALLY KNOWN AS H. J. HARDING LOOK FOR WEAVING PATTERNED FILE FABRICS l4 Sheets-Sheet '7 Filed Oct. 29, 1946 July 26, 1949. J. H. HARDING 2,477,249

GENERALLY KNOWN AS H. J. HARDING. LOOK FOR WEAVING PATTERNED FILE FABRICS Filed on. 29, 1946 14 Sheets-Sheet a generally known ad y 6, 1949. J. H. HARDING 9 2 GENERALLY KNOWN AS H. J. HARDING LOOK FOR WEAVING PATTERNED FILE FABRICS Filed Oct. 29, 1946 14 Sheets-Sheet 9 Jy 2, 19. J. H. HARDING 9 GENERALLY KNOWN AS H. J. HARDING Loou FOR WEAVING PATTERNED PILE mamas Filed Oct. 29, 1946 14 Sheets-Sheet 1O 6W krww 1949- J. H. HARDING 2,477,249

GENERALLY KNOWN AS H. AR ING LOOM FOR WEAVING PATTERNED FILE FABRICS Filed Oct. 29, 1946 14 Sheets-Sheet l1 j f'gja w erlo 10mm 0 J. H. HARDING GENERALLY KNOWN AS H. J. HARDING July 26, R949.

LOOM FOR WEAVING. PATTERNED FILE FABRICS 14 Sheets-Sheet 12 Filed Oct. 29, 1946 Jufly 26, 1949. J. H. HARDING GENERALLY KNOWN AS H. J. HARDING [100M FOR WEAVING PATTERNED PILE FABRICS Filed Oct. 29, 1946 14 Sheets-Sheet l3 J. H. HARDING GENERALLY KNOWN AS H. J. HARDING LOOM FOR WEAVING PATTERNED FILE FABRICS 14 Sheets-Sheet 14 Filed Oct. 29, 1946 TX'Y s qenera Patented July 216;, 1949 LOOM FOR WEAVING PATTERNED FILE FABRICS John Henry Harding, generally known as Harry J. Harding, Philadelphia, Pa... assignor to C. H. Masland & Sons, Carlisle, l'a. a corporation of Pennsylvania Application ctobcr 2 9,1946, Serial a... 106,353

'1 Claims. (01.139-39) My invention relates to a loom for producing a pile fabric having two different types of pile, high and low, cut-and uncut, either'or both, produced on one cycle.

The present application is part'of my application Serial No. 631,202, filed November 2'7, 1945. for Fabric, process and loom, now abandoned. Fabric subject matter relating to the present application is described and claimed in my copending application Serial No. 706,354, for Fabric and process, filed October 29, 1946. Process subject matterrelated to the present application is described and claimedin' my.

copending application Serial No. 772,080 for'Process of weaving a pile fabric, filed September 4, 1947.

A purpose of my invention is to weave-both a cut and an uncut pile tuft, either or both as the pattern requires, on a given cycle of .loom o'peration, and which in the finished fabric-willv be in the same transverse line of tufts. I

A further purpose is to employ two heights. of pile in the same transverse rowof tufts in the finished fabric, either or both of which may, be cut or uncut.

A further purpose is to weave a pile fabric with one tuft raised on the second of a pair or weft shots and another tuft raised on a weft miss, prefa continuation in v and again miss a pick; andthen repeat the cycle,

beginning with the ,heddle positions unchanged, the lash or pile down and pick, etc.

A further purpose is to provide eight revolutions of thecrank shaft'to one revolution of the treadle box, and alternate two solid picks and two blank picks, to allow for change in the character of wire as the pattern requires.

A further purpose is to reverse the fine chain warps between adjacent solid picks, to correspondlnglv reverse the stuffer warp between ad-,

jacent solid icks and to keep it be ow the pick positions at b ank picks and to rovide uncut pile coincident with one of the solid picks and cut pile erably on the second of a pair of weft misses,

either or both as the pattern requires, in a. given loom cycle.

A further purpose in the Weave of a floor ing is to insert only two shots of weft for two wires which are used selectively on one weaving cycle as the pattern may require.

A further purpose is to form a pile fabric over a cut wire and an uncut wire both inserted on a given cycle, while inserting only two weft shots during the cycle. A"'further purpose is to provide a pile fabric having alternate out and uncut pile and in which there are two solid picks and then two blank picks.

A further purpose is to provide a pile fabric in which there are l6 wires for each It solid picks but for 32 beats of the lay.

coverbetween one pair of solid picks and the next, as required by the pattern.

Theflne chain w rns are reversed between each adjacent pair. of solid picks and then remain one up and the other down durin 'the n xt two blank picks. being reversed between the following adiacent pa r of solid picks to then remain in t e same raised or lowered pos tion until the next two adjacent solid picks. The result is that the fine chain warp heddles are one lifted and the other lowered between two solid picks and remain in their lifted and lowered posit on until the next pair of solid icks. between which they are lowered and lifted respectively.-this action keeping on progressively. Meantime the stuffer warp heddle is lifted between each pair of solid picks. lowered immediately after, and helddown during the intermediate blank picks and the first succeeding solid pick, then lifted and lowered again over the second of the adjacent solid picks.

This invention relates to the formation of a relief pattern in weaving pile fabrics through control of the positionand relation of cut and uncut pile tufts and to a process of manufacture of the fabric.

A further purpose is to use the difference inappearance between the surfaces secured by cut as compared with uncut pile tufts as a means of weaving a design or figure within transverse rows of tufts in a pile fabric.

A further purpose is to use a standard type of loom with suitable control of the picking cam so as to lntersperse a pair of solid picks and a pair of blank picks and suitably to control the heddles lifting and lowering the chain warps, stuifer warp and pile warps and alternate or intersperse cutting and non-cutting pile wires in accordance with the extent and position of cut pile tufts and uncut pile tufts by which the design is to be ef-' take a number of solid picks at intervals between blank picks, each of which shall have a suitable relation, preferably each to be equal to the number of pile wires used, cutting the tufts formed by some of the pile wires and not cutting the tufts formed by intervening pile wires, in a number and relation of cut and uncut tufts corresponding with the field and design of the pile fabric woven.

A further purpose is to intervene blank picks preferably in pairs between solid picks in pairs with cut and uncut pile respectively alternating, one opposite the solid picks and the other opposite the blank picks.

A further p se is to obtain an embossed effect in pile fabric weaving without unnecesaary utilization of weft yarn by raising the pile over the second of a pair of weft shots in the cycle and/or as the pattern requires raising the same or another pile yarnto a different height over one of two misses in the shuttle operation in the same cycle.

A further purpose is to bring pile tufts of dlflerent kinds into the same transverse row of pile tufts in the finished fabric while employing mispicks between the respective different tufts in weaving, without crossing the chain warps in the interval between the tufts.

Further purposes appear in the specification and in the claims.

In the drawings I have chosen to illustrate two embodiments, of numerous types of looms in which the invention might be employed, choosing the forms shown from the standpoint of convenience of illustration, satisfactory operation and clear exempliflcation of the principles involved.

Figures l to 6 inclusive are diagrammatic, longitudinal illustrations of the steps in weaving the fabric of the invention.

Figures 3*, 4", 5, and 6 are enlarged diagrammatlc illustrations of fragments of the respective Figures 3 to 6 inclusive.

Figure '7 is a diagrammatic, longitudinal section of the preferred form of the weaveof the present invention prior to cutting of the pile.

Figure 8 is a diagrammatic, longitudinal section similar to Figure '7, but showing the out pile in out form.

Figure 8 is a longitudinal section of the completed fabric.

Figure 9 is a diagrammatic plan view of the fabric of the invention.

Figure 9" is an enlarged fragment of Figure 9.

Figure 10 is a perspective view of one loom to which the invention has been applied.

Figure 10* is a fragmentary diagrammatic elevation of a jacquard mechanism.

Figure 10 is an enlarged central vertical section of the jacquard mechanism of Figure 10 Figure 11 is a partially diagrammatic fragmentary perspective of the two sides of the loom. showing one form of picking mechanism.

Figure 12 is a perspective of a picking cam assembly for a four shot weave using the picking motion of Figure 11.

Figure 13 is a front elevation of a variant picking mechanism.

Figure 14 is an enlarged fragmentary perspective of the picking latch mechanism of Figure 13.

Figure 15 is a fragmentary perspective of the reverse side of the mechanism shown in Figure 14, detached or pulled apart to show the intor-relations of the parts.

Figure 16 is a diagrammatic view showing the '4 means of connecting the picking mechanism on the two sides of the loom.

Figures 17 and 18 are fragmentary side elevations of wires.

Figures 19 to 22 inclusive are diagrammatic longitudinal sections of'variant weaves embodying the invention. 7'

In the drawings, like numerals refer to like parts throughout.

In the present invention, a two shot fabric is produced since there are two wefts per cycle, but the treadle box motion, the take-up and the pick are in the preferred embodiment on a four shot basis since there are preferably two miss shots per cycle.

Referring particularly to Figures 1 to 6 inclusive, which illustrate the weaving of a two frame Wilton carpet (floor covering), a loom is diagrammatically illustrated of any suitable design, having reed 20, front chain warp heddle 2i, rear chain warp heddle 22 and stuifer warp heddle 23, as well as lingoe heddles 24 and 25 which carry the pile warps in raised or lowered position. The double chain warp sets 26 and 21 are supplied from beam 28. The stuiier warp 29 is mounted on stuffer beam 20. It will be evident, of course, that any suitable number of stufiers desired may be employed.

Any suitable number of pile yarns may be used, of which two are illustrated at SI and 32. supplied from creel frames 33 and 34. The invention has been applied successfully using up to six pile warps, and the choice of two pile warps herein is for the sake of simplicity in illustration. As well known in the art, the stuflers and chains are supplied over jumbos 35 and 36.

Each of Figures 1 to 6 corresponds to a different rotation on the crankshaft in a normal loom.

Figure 1 shows the assumed condition at the beginning of a cycle, based upon the production of a two shot fabric using a four shot motion. At the beginning of the cycle shown in Figure l, the front chain heddle 2| is up, the rear chain heddle 22 is down and the stuil'er warp heddle 23 is down, while the lingoe heddles 24 and 25 are also down. In this position, the first shot of weft 31 is taken, passing under chain warp 2'! and over all other warps. At the end of the step shown in Figure 1, the reed moves forward beating up the weft or filling shot in the conventional manner.

As shown in Figure 2, the heddles are reversed in this position, the front chain heddle 2l' moving down and the rear chain heddle 22 and stuffer warp heddle 23 moving up. Some-lingoe heddles 24 rise fully, lifting the pile warp 3I,,while the other lingoe heddles 25 go up half way, as the pattern requires. In this position, a shot of weft 38 is inserted under the stufier 29, the pile warps 3i and 32 and the chain warp 26, and above the chain warp 21. A wire 38 is inserted above everything except the pile warp 3i, and the reed moves forward beating up the weft.

In the position of Figure 3, the chain warp heddles remain unchanged while stufl'er warp heddle 23 moves down, and lingoe heddles 26 and 25 carrying the pile likewise move down. In this position the loom misses a pick, although the reed comes forward and again beats up the previous shot. As shown in Figure 3 the forming pile at this position includes the two wefts 31 and 3B and the wire 39, with no additional weft. The last operation inserted either a, cut wire or an uncut wire, but in the preferred embodiment as later explained, it will be an uncut wire. This step is convenient to conform to a four step cycle commonly used and may if desired be the occasion for the removal of wires.

As shown in Figure 4, during the next step the front and back chain heddles andthe stuffer heddle remains the same while some lingoe heddles 24 come up half way and other lingoe heddles 25 come up fully as the pattern requires. A wire 40 is inserted below the pile warp 32 and above all other warps, while the weft shot is missed. As shown in Figure 4, the position of the forming fabric is substantially the same-as illusduced on that cycle, once the wires are removed.

' In the preferred embodiment of the weave of the and the other opposite the second of a pairrof trated in Figure 3 since the previous shot was a miss. The reed comes forward and beats up the weft 38 in the usual manner.

The four steps described represent a complete cycle. To illustrate the relation with the succeeding cycle, a portion of the next cycle is illustrated, in Figures 5 and 6.

In Figure 5, the front and'rear chain warpheddles and the stuffer'heddles'remain the same,

the lingoe heddles both remain down and the weft shot 4! is taken passing under the chainwarp 26 and above all other warps. The condition of the fabric resulting from the previous cycle is represented in Figure 5 with two wefts in position and two wires also in position, one of the wires corresponding tothe second miss shot.

As illustrated in Figure 6, the next step results in a reversal of the chain warp heddles and stuifer warp heddle, while some lingoe'heddles 24 are up and other lingoe heddles 25 are half way up, as the pattern requires. A shot of weft 42 is inserted below all warps except chain warp 26. and a wire is inserted above all other warps except pile warp 3|. The condition of the fabric resulting from the previous operation step is illus-.

trated in Figure 6.

The heating up of the lay at the mispick position and on the next pick performs an important function, which will be understood by reference to Figure 6". It will be noted that once the wires are withdrawn, there is nothing in the structure of the fabric separating the different tufts formed over the respective wires 39 and 40. The beat of the lay at the mispick position and the next pick applies tension on the chain warps and the pile, and as soon as the wires are removed this tension pulls the different tufts formed over the wires 39 and 40 into the same transverse line of tufts, so that then they will appear from the face of the fabric to be in the same transverse line of tufts, as in fact they previously have been from the standpoint of the structure of the fabric.

The successive wires inserted will normally be alternately low wires and high wires. Due to the fact that if the low wire is inserted last in the cycle, it will not be protected against being pushed up by the reed, it is very desirable to insert the low wire first and the high wire second in thesequence. Thus wire 39 is preferably a low wire and wire 40 is a high wire. By this procedure the wefts of the next cycle tend to bind the high wire in position and it protects the low wire ahead of it from being improperly forced up by the reed.

It is also very desirable to use a combination of uncut and cut wires, the low wire being normally a non-cutting wire to produce an uncut mispicks, the action of the subsequent beat of the lay applied to the misplcks and to the next pick creates the tension in the chain warp and in'the pile which. on removal of the wires, brings all pile tufts formed ona given cycleinto the same transverse line of tufts. Thus though Figvure 7 and other similar figures show high pile and lowpile tufts which appear to be in a different transverse line, when the fabric has been beaten up and the wires removed the various tufts'transversely across the fabric formed on a given cycle, whether they be high tufts or low tufts or cut tufts or uncut tufts, are brought into the same transverse line of tufts. This is important from the standpoint of appearance. economy in material used in production of the fabric and wearing qualities of the fabric.

The nature of the fabric 43 will be better understood by reference to Figure 7 which shows diagrammatically a sequence of non-cutting wires 44, desirably relatively lower, and cutting wires 45 desirably relatively higher, The pile formed by the loops 46 extending over the non-cutting wires is carried to the back of the fabric at 41, coming up again as the pattern may require. In Figure 7 the loops 46 are brought up over each of the uncut wires; whereas in actual practice they would normally only be brought up at points where the pattern required loops rather than cut pile. Likewise the loops 48 subsequently to be out are shown in Figure 7 as carried over each of the cutting wires, whereas in actual practice they would normally not be carried up where uncut loops were being used on the particular cycle and lateral position.

It will thus be evident that for each cycle there are two wires of different dimensions or types inserted, but the pile will normally be carried over only one of them in accordance with the demands of the pattern. Both of these wires form tufts which, after the wires are removed, lie in the same transverse row. The weft shots 49 and 50 are in pairs between which the chain warps 5| and 52 cross, the intermediate spaces 53 and 54 being indicated as miss shots. ,Actually in the finished fabric the wefts will, of course, be positioned with weft 49 of each pair to the front of the fabric and weft 50 of each pair to the back of the fabric, and the spaces corresponding to the miss shots will be lost, bringing all solid shots pile loop, and the high wire being a cutting wire tration retain the conventional positions which they had when held by the wires. The relatively low uncut tufts or loops 46 appear in a group at 56 corresponding to a portion of the pattern calling for uncut loops, while the cut tufts 51 resulting from cutting of the loops 48 correspondingly conform to a portion of the pattern calling for cut pile.

One of the important features of the invention with the convention of illustrating the fabric before the beat.

Figure 8 shows more clearly the actual form of the completed fabric, with wefts 58 at the back and wefts 49 at the front, and low uncut pile tufts 58 standing in the same transverse line of tufts and in front of higher out pile tufts 59', while higher cut pile tufts 59 stand in the same transverse line of tufts with and in front of low uncut tufts 58 Thus it will be seen that in the finished fabric the cut and uncut loops are in the same transverse row.

Figures 9 and 9* illustrate the face of a pile fabric according to the invention. The uncut pile areas 68 in base relief are interspersed with cut pile areas BI which are higher and more prominent, causing an embossed or mosaic effect.

Certain tufts 68' of the areas 68 are on the same transverse row of tufts as other tufts 6| in the areas 6 I. One of the important advantages of the invention is that it is possible to place the cut and uncut or high and low pile tufts in the same transverse row of tufts.

The loom of the present invention may correspond to any standard design with structural modifications to accomplish the special weave. The invention will normally be applied by modifying a standard Wilton loom.

Figure 10 shows a typical Dobcross Wilton loom omitting the jacquard (shown in Figures 10* and 18 which has been modified as later explained to produce my special weave. The loom is of well known type, having a reed '62, heddle harness 63, treadle box levers 64, treadle box 65, picking sticks 56, take-up 61, spike roll 68, take-up roll 69, wire motion mechanism 18, and jacquard standards I I.

Figures 10 and 10 illustrate a conventional jacquard mechanism consisting of an upper frame I2 mounting the usual jacquard mechanism I3 having end frames 14 in which are vertically slidably mounted an upper grid 15 and a lower I grid 15.

The jacquard mechanism I3 also comprises the usual series of wires ll, of which only two are shown, but of which one will be used for each of the pattern threads of each pile warp. Lingoe heddles 24 and 25 are suitably operated by the wires 11.

Each jacquard wire has the usual upper hook 18 which is adapted to be engaged by a bar I9 of the well known in the art of weaving, to present the suitably punched cards of the string 83 successively to the operating ends 85 of the needles 82.

The card cylinder 84 is mounted for intermittent rotation, in the usual manner, in bearings 86 carried on the ends of axially movable rods 81 slidably mounted in bearings 88 on the frame I4 of the jacquard mechanism 13, and the usual hooks 89 are provided for turningthe cylinder one step at a time for each reciprocation of the cylinder toward and away from the needles 82.

The cylinder is reciprocated by operating rods 98 connected at one end to the bearing heads 86 on the cylinder supporting rods 87, the opposite ends of the operating rods 98 being connected to the outer ends of levers 9|. The levers 9I are fixed on rock shafts 92 rotatably mounted in frames 93 supported by the superstructure 12.

On the cylinder rock shaft 92 is a lever 94 the other end of which is operatively connected to a suitable link 95 driven by the loom as well known I in the art.

The grids I5 and I6 are coupled together and operate in unison with differential rise and fall between the two grids, as well known. The upper grid 15 is connected at each of its opposite ends by links 96 to one end of levers 91 pivotally mounted on a rock shaft 98 having bearing support on the frame 93, the opposite lever end being connected to a link 99 for operation of the frame from the loom in the well known manner.

The lower grid 16 is operatively connected at each of its ends by a link I88 to one end of a lever II, of which there are two, only one being shown. The levers I8I are rigidly secured to a rock shaft I82 which is rotatably mounted in the frame 93. One of the levers II is provided at its opposite end with an operating link I83 which connects to the outer end of lever 91.

As well known in the art, the card cylinder moves toward the ends of the needles 82 of the jacquard mechanism once in any single step of the weaving operation and each card in the string is adapted to select certain pattern threads to be raised in a manner to form the pile face of the fabric and produce the desired design.

In order to modify the loom of Figure 10 to produce my special weave, it is of first importance to change the picking mechanism so that the cycle will begin with two picks and follow with two mispicks. As shown in the modified treadle box of Figure 11, power to drive the picking mechanism is transmitted through bottom shaft I84 running from side to side of the loom on suitable bearings, not shown, turning in the direction of the arrow, and carrying bevel gear I85 which drives cooperating bevel gear I86 on counter shaft I81 carried by suitable bearings, not shown. The counter shaft l8'I also carries pinion I88 meshing with treadle box pinion gear I89 on treadle box shaft II8 supported in suitable bearings, not illustrated. Treadle box gear I89 drives stuifer heddle cam II I and chain heddle cams I I2 and H3, of well known character. Also turning on the same shaft is picking change cam I I4 shown more in detail in Figure 12.

The stufier and chain warp heddle cams may be identical with those normally used, preferably modified at approach and release portions to give quick pick-up and release with change of driving speed. In the normal prior art construction a one-to-one ratio has been used on the gears I85 and I86, whereas in the present invention it has been found desirable to employ a one-to-two ratio, thus cutting th heddle cam speed in half. The

ratio between the pinions I08 and I09 is one-totwo, so that the ratio between the bevel gear I and the treadle box shaft I I0 is one to four, giving one rotation of the picking change cam II4 for every two cycles, or one-half rotationper cycle. The heddle cam speeds are cut in half with respect to the prior a.t practice.

The mechanism for transmittin heddle motion from the cams consists of the treadle box levers '64, 54 and 54 which are pivoted at I54 and provided with followers, not shown, which ride the cams s well known in the art. As the treadle box levers are moved, they transmit the motion to the heddle harnesses through rigging such as chains II5, passing over suitable sprockets II6 as in prior practice.

At the two sides of the doom, or at opposite ends of the bottom shaft I04, I provide a left hand picking disc I" having a picking hammer H9 and a right hand picking disc II9 having a picking hammer I20, the respective picking hammers'being 180 out of phase as shown in Figure 11, so that when the hammer at one side is in picking position the hammer at the other side is 180 removed therefrom. At each side of the loom is a picking shaft I2I on the left, and I'22 on the right, carrying a picking tongue I23 on the left and I24 on the right, which are located toward the outside of the loom with respect to the picking disc and at the proper time are engaged and depressed by the appropriate picking hammer. Th picking shafts are supported in suitable bearings not shown. Picking shaft I2I merely rotates, but picking shaft I22 both rotates and moves longitudinally as later explained. On each picking shaft is a picking wing I25 on the left and I29 on the right, the two picking wings being oppositely directed as well known. Each picking wing through its leather strap I2I applies an impulse to the appropriate picking stick 69 suitably pivoted at I23 and spring urged to return at I29 toward a suitable abutment. The action of I the picking stick in throwing the shuttle is of course well known in loom design.

The picking change cam II4 operates on a follower I 30 (Figure 12) at the end of a bell crank or radially outer portion I of the picking change cam. This places picking tongue I24 in the position shown in full lines in Figure 11. The picking hammer I20 at the right is 180 out of the position shown in Figure 11; or in picking position, and the shuttle is thrown from right to left. Nothing happens regarding the shuttle on the left because the picking hammer is 180 out of phase and the shuttle is not. over in the left hand box at the beginning of this step.

In the next step, as shown in Figure 2, the picking change cam moves on until the follower I30 is in the low" or radially inner portion I of the cam path, moving the right hand picking tongue I24 out of picking position. This is immaterial in any case because the right hand picking hammer I20 is 180 removed from picking position and the shuttle is over on the left so that no pick could occur from the right. Over on the left, however, thepicking hammer III is in picking position and encounters the picking tongue I23, throwing the shuttle from left to right. 7

In the next step, shown in Figure 3, no picking action can occur from the left because the picking hammer H8 is 180 out of picking position, and the shuttle is on the right. The follower I33 is still in a radially inner or low" position I of the picking change cam, so that the right hand picking tongue I24 is in the dot-and-dash or inoperative position of Figure 11, and no picking can occur, notwithstanding that the shuttle is in the right hand box. This is the first of the misses on the cycle.

In the next step, corresponding to Figure 4, the follower I30 is still in a 'low or radially inner portion I H of the picking change cam, and the picking tongue I24 on the right is in inoperative ormiss position, so that there is a miss from the right. Over on the left the picking hammer III is in picking position and actually strikes the lever I3I pivoted at I32 to vertically urge the pull rod I33, on the opposite end I34 of the bell crank, pulling or pushing on the lever I35 on picking change shaft I36 running from left to right of the loom and mounted in suitable bearings, not shown. On the right hand side of the loom, shaft I33 carries picking shift lever I 31 whose forked end I38 engages between two abutments I39 on longitudinally movable picking shaft I22. Thus when the follower I30 is on a "high" of the cam, the picking tongue I24 is in picking position and adapted to be engaged by the picking hammer I20, while when the follower I30 is on a "low of the cam, the picking tongue I24 is moved to the position shown in dot and dash lines in Figure 11 so that it is missed by the picking hammer I20 and picking does not occur.

The picking change cam as shown in Figure 12 has a comparatively short "high or outer cam portion I40 corresponding in length to one step in the cycle, and a substantially longer low or inner radial cam portion I4I' corresponding in picking tongue I23 and operates the picking stick 66 at the left, but there is a miss because the shuttle is not in the left hand box and cannot be thrown.

Thus by this procedure the required sequence in the preferred embodiment of two picks and two misses is obtained with very little departure from the standard Dobcross picking mechanism.

Figures 13 to 16 inclusive illustrate the changes required in order to apply the picking motion of t present invention to a Lansdowne loom.

The driving shaftl42, though positioned transversely to the bottom shaft I04 above referred to. moves at the same speed as the bottom shaft I04 and may be considered to be the equivalent thereof. The shaft I42 carries a crank I43, .which operates a connecting rod I44 which extends horizontally across from one side to the other of the loom, and on each side of the loom operates an identical but opposite counterpart picking rocker I45 pivoted at I46 to rigid frame structure I", and pivotally connected to the connecting rod I44 at I48. Each picking rocker I45 carries an adjustable picking abutment I49. The picking abutments I49 are continuously carried b'ythe crank through an are from one limiting position at the left of their stroke as shown in Figure 13 to the opposite limiting position somewhat less.

than toward the right, as well known.

Loosely pivoted on the same shaft I46, behind the picking rocker in Figure 13, is an opposite counterpart picking arm I50 at each side of the mechanism, connected by a strap I5I extending through an opening in a spring support I52 to a spring abutment I52, which when pulled to the left in Figure 13 compresses a compression spring I53. The structure at the right, not shown in an opposite counterpart.

The picking arm I50 carries a picker strap I54, suitably of conventional type, which connects to a pivoted picker stick 66 of well known character.

The picking motion is determined by a gear I55 driven from a gear I58 on shaft I42, at one fourth the speed of shaft I42. Gear I55 is on shaft I51 carrying picking change cam I58. Bearlugs for the shaft are of any suitable character, not shown. The picking change cam I58 turns one-half revolution per cycle and has two high portions I59 each extending slightly over 45 and two low portions I60 each extending slightly over 45, with suitable transition portions between. A follower lever I6I on fixed pivot I62 carries a follower I63 which engages the picking change cam, and is spring urged toward the cam by a spring I64 suitably of tension type connected to a spring abutment. The opposite end of the follower lever I6I is pivotally connected at I65 to a follower rod I68 illustrated more in detail in Figures 15 and 16, which connects to and operates a bell crank lever I01 pivoting at I68 on bearings not shown, and having at its opposite end a slot I69 engaging a pin I10 for moving in and out a sliding latch control bar I1I moving longitudinally in a latch I12 on a fixed pivot I13 in the frame structure, and spring urged toward latching position by a tension spring I14 from a suitable anchorage. The end I15 of the latch control bar III- when in its lower position with respect to Figure 15 is engaged by the picking abutment I49 on the picking rocker I45 near the upper end of its stroke.

The latch I12 by its latching dog I16 engages a latching abutment I11 (Figure 15), on the picking arm I50, when the latch is in latching position, holding the picking arm against release of the pull of spring I53 and preventing throwing of the picker stick. I

When the cam moves to a low, the latch control bar moves to lower position (Figures 13 to 16 inclusive) where it can be engaged by the picking abutment I49, the latch is opened, releasing the picking arm I50 and permitting spring I53 to throw the picker stick. In case cam I58 prevents the latch control bar from engagement by the picking abutment I49, the latch cannot be released and the picker stick cannot be thrown, so that there is a miss.

A projection at I18 from the back of the picking rocker I45 engages the picking arm I50 on the return stroke and returns the arm to the position shown in Figure 13, compressing the spring I53 and permitting the latch spring I14 to restore the latch to latching position, and holding the picking arm in this'position until the latch is next released.

It will be evident of course that the picker stick and the picking mechanism on the right hand side of the loom will be opposite counterparts of those here shown at the left hand side of the loom, as indicated in Figure 16, where it is seen that the bell crank I61 is connected with its arm engaging follower rod extension I66 extending up rather than down, and the arm engaging the latch control bar "I oppositely directed from that on the left. Likewise the picking rockers, arms and latches are opposite so that the forward stroke on the left which creates a pick or a miss pick corresponds to the return stroke on the right, and vice versa.

To summarize the operation of the form of Figures 13 to 16 inclusive, in the first step correspending to Figure l, with the shuttle in the right hand box, the cam follower I63 has just begun to arrive at a radial inner or low" portion I60 of the picking change cam I58, moving the picking latch control bars I1I at both sides of the loom into the picking position where they can be intercepted by the picking abutment I49. However, the picking rocker I45 on the right is then moving toward the position for engagement between the abutment I49 and the end I15 of the latch control bar, while on the left the picking rocker I45 is on its return or inoperative stroke. Therefore, on the right the picking abutment I48 engages the latch control bar, releasing the latch and permitting the spring I53 to throw over the picking arm I50, which in turn pulls the picker strap I 54 and the picker stick and throws the shuttle from right to left.

In the next step as shown in Figure 2,the follower I83 is still on a radial inner or low portion I 60 of the picking change cam I58, the shuttle is in the left hand box and the picking rocker at the left is in its operative stroke. Therefore at the left the picking abutment I49 strikes the end I15 of the latch control bar, releases the latch, and permits the spring I53 to throw over the picking arm I50, the picker strap I54 and the picker stick 66, throwing the shuttle from left to right. No operation occurs on the right because the shuttle is not in the right hand box and the picking rocker I45 on the right is on its return stroke.

In the third step corresponding to Figure, 3, the cam follower I63 has arrived at a high or radially outer portion I59 of the picking change cam I58, moving the latch control bars I1I to the upper or miss position, so that, while the picking rocker I45 on the right makes a stroke in the operative direction, the picking abutment I49 does not encounter the picking control bar, the latch is not released and the shuttle is not thrown. Over at the left the picking rocker I45 is making its return stroke.

In the fourth step of the cycle as shown in Figure 4, the follower I63 is near the end of a radially outer portion I59 of the picking change cam I58, so that the latch control bars I1I are still set for a miss. The picking rocker I45 on the right is on its return stroke, but the picking rocker at the left is on its operative or forward stroke, but accomplishes nothing due to the fact that the picking abutment I49 does not encounter the picking control bar "I. In any case there could be no picking from the left, as the shuttle is in the right hand box, but the shifting of the picking control bar at the left in this case prevents throwing the picker stick in the absence of the shuttle, which in the case of the heavier mechanism of Figures 13 to 16 might cause some damage to the equipment.

The only other change which normally would be encountered in a loom to produce the special weave under discussion would be the change in the take-up speed to make it accommodate the rate of production of the fabric which is half the normal take-up speed, due to the two mispicks. This feature is obviously merely a matter of choosing suitable gear ratios.

In Figures 17 and 18, I illustrate suitable conventional wires, of which Figure 17 shows a cutting wire I 19 having a cutting portion I and a wire portion I8I which is desirably a high wire capable of producing a high loop. The wire I82 of Figure 18 is normally a low wire and a non- 

